DE102008024090A1 - Switching regulator with PWM controller - Google Patents

Abstract

The invention relates to a working in shunt mode, self-powered switching regulator with one of a current source (I) via a charging diode (V2) up and reload storage capacitor (C1) and with a PWM regulator, the current source via a switching transistor (V1) (I) shorts according to an upper and a lower switching threshold for the charging voltage of the storage capacitor (C1) or for recharging the storage capacitor (C1) releases. The problem to be solved is the reduction of the construction volume, the material and assembly costs as well as the own power requirement. For this purpose, the PWM regulator consists of a hysteresis-based reset controller (V3) whose supply connections (Vcc, GND) are connected at least indirectly to the storage capacitor (C1) and whose reset output (Reset) controls the switching transistor (V1).

Description

The The invention relates to a shunt-mode switching regulator with a pulse width modulation controller (PWM controller). Find such switching regulator with self-powered electronic devices from current transformers, especially of utility meters or triggering systems for example circuit breakers and motor protection switches, Use.

Many electrical devices, such as consumption meters or tripping systems for motor-protective circuit-breakers and circuit-breakers with an electronic operating principle, do not have a fixed power supply, but are supplied with power independently of the voltage flowing through them. In this case, the supply current for the electronic device, and often at the same time the measurement signal, generated by current transformers from the single or multi-pole load current. The one or more output currents of the current transformers are rectified by rectifier diodes and linked together. From the current obtained in this way, which is proportional to the primary current, it is then necessary to obtain a constant voltage supply suitable for supplying the measuring or tripping device. This is usually done via a working in shunt mode PWM switching regulator accordingly 1 ,

Current transformers with secondary-side rectifier circuit are well known and not listed here for simplicity, but represented by a symbolized constant current source. Via a diode V2, the constant current I charges a storage capacitor C1 until a certain charging voltage is reached. A comparator V3 'is powered by the charging voltage. When an upper limit value of the charging voltage is exceeded, the PWM regulator having a comparator V3 '(shown within the dashed frame) switches via a resistance divider R1, R2 through a switching transistor V1, which then short-circuits the current source. The supply of the electrical device, here represented by the load resistor R _L, now takes place solely from the storage capacitor C1. The switching signal for the transistor V1 is connected to the output of the comparator V3 'via a load resistor R3. The diode V2 prevents a discharge via the transistor V1. If the capacitor voltage drops below a lower limit value, the transistor V1 is switched off again via the PWM regulator so that the storage capacitor C1 is recharged. The self-running PWM controller is constructed here with a comparator circuit. A reference voltage source, here realized by a series resistor R5, a Zener diode V4 and a capacitor C2, serves to generate the switching threshold. Another resistor divider R4, R6 serves to detect the charging voltage at the storage capacitor C1. About the comparator V3 'is the setpoint comparison and the control of the switching transistor V1. A return resistor R7 determines in conjunction with the load resistor R3 via positive feedback the switching hysteresis of the PWM controller.

Of the described switching regulator is so or more or less modified Form already used in a variety of switching devices. In addition to the construction with a comparator and PWM controller with an operational amplifier are known. Various reference voltage sources are also used. Depending on the structure of such a switching regulator and depending the comparator or operational amplifier used and the used Reference voltage source is the self-consumption of the control circuit a few hundred microamps. The number of required components for the PWM regulator is included at least eight, the number of connection elements or terminations at nineteen. For small switching devices, such as B. motor protection switch, the only a very small installation volume for current transformers and trip electronics enable, are the known switching regulator therefore in terms of relatively high space requirements, the relatively high self-consumption and the relatively high component and assembly costs disadvantageous.

Of the The invention is therefore based on the object switch regulator in shunt mode with PWM controller with regard to the required construction volume, the material and assembly costs as well as the own power requirement to reduce.

outgoing of a switching regulator of the type mentioned is the task according to the invention the characteristics of the independent Claim solved, while the dependent Claims advantageous Developments of the invention can be seen.

The inventive circuit arrangement, the entire comparator circuit including reference voltage source and detection of the charging voltage is replaced by a single block from the digital technology, namely by a reset controller. Reset controllers are usually provided for the safe start, ie for enabling, of a microcontroller during the startup of the power supply in order to prevent undefined states of the output ports of the microcontroller during the startup phase. Reset controllers are integrated circuits in the usually three-pole housing, which are both inverting and non-inverting. Reset controller is available with staggered threshold voltages, so that a suitable nete selection to be made according to the supply voltage to be generated. A defined switching hysteresis is already integrated. Available on the market is a wide range of reset controllers, which are characterized by a very low power consumption of a few microamps and a very reasonable price.

at Use of a reset controller with output-side open-collector circuit is a working resistor between the reset output and the high Provide supply connection of the reset controller.

In Advantageously, one serves between the high-level supply connection and its associated Connection of the storage capacitor arranged additional resistance in conjunction with a between the reset output and the high Supply connection arranged working resistor to increase the Switching hysteresis. One between the overhead supply connection of the reset controller and its associated Connection of the storage capacitor arranged Z-diode is used in advantageous way to increase the supply voltage to be generated. Both versions are combined as needed in an advantageous manner.

Of the PWM regulator can be used advantageously both with a noninverting Reset controller in conjunction with a designed as an N-channel MOSFET Switching transistor as well as with an inverting reset controller in conjunction with a switching transistor designed as a P-channel MOSFET accomplished become.

Further Details and advantages of the invention will become apparent from the following explained with reference to figures Embodiments. Show it

1 the already described switching regulator according to the prior art;

2 a switching regulator according to the invention with non-inverting reset controller;

3 a switching regulator according to the invention with inverting reset controller;

4 another embodiment of the PWM controller and

5 : Another embodiment of the PWM regulator.

In a known manner, one or more current transformers and a rectifier circuit form an arrangement which supplies the switching regulator and in 2 is shown symbolically as current source I. Via a charging diode V2, the current source I charges a storage capacitor C1. The charge voltage present across the storage capacitor C1 forms the supply voltage for an electrical load R _L. Parallel to the current source I designed as an N-channel MOSFET switching transistor V1 is arranged. A self-running PWM controller surrounded by the dash-dot frame is supplied by the charging voltage and regulates it within narrow fluctuation limits. When an upper switching threshold of the charging voltage is reached, the PWM regulator controls the switching transistor V1 via a voltage divider R1, R2 connected to the reference potential (ground), whereby the current source I is short-circuited via the drain-source path of the switching transistor V1. As a result, no additional charge is supplied to the storage capacitor C1, the charging diode V2 preventing a discharge of the storage transistor via the switching transistor V1. If the charging voltage drops below a lower switching threshold as a result of the discharge via the load R _L , the switching transistor V1 is closed by the PWM regulator, whereby the storage capacitor C1 is recharged by the current source I.

The PWM controller will go to 2 by a non-inverting reset controller V3 and a load resistor R3, which is arranged between the open-collector circuit formed in the reset output and the high-level supply terminal Vcc of the reset controller V3. The reset controller V3 responds when a certain voltage between the supply terminals Vcc and GND is exceeded by its reset output goes into the non-conductive state. As a result, the switching transistor V1 is turned on via the load resistor R3 and via the resistor divider R1, R2. Due to the now lack of recharging the charging voltage and thus the voltage between the supply terminals Vcc and GND drops below the lower threshold. The lower switching threshold results from the response threshold of the reset controller V3, ie the upper switching threshold, reduced by the switching hysteresis already integrated in the reset controller V3. When falling below the lower threshold, the open-collector circuit of the reset output goes into the closed state. As a result, the switching transistor is transferred via the resistor divider R1, R2 in the locked state, whereupon the storage capacitor C1 is recharged until it reaches the upper switching threshold.

The switching regulator according to the invention can be readily constructed with an inverting reset controller V3. This is how in 3 to replace the switching transistor V1 by a P-channel MOSFET and the voltage divider R1, R2 to connect to the high supply potential.

In the marked by the dot-dash frame PWM controllers of the switching regulator according to the invention 2 and 3 were compared to the PWM controller of the prior art switching regulator after 1 own power consumption reduced to one third, the number of components from eight to two and the number of terminations from nineteen to five.

If the switching hysteresis of the reset controller is insufficient, this can be increased in a simple manner. 4 shows such a structure for a PWM controller with a noninverting reset controller V3. Here, the switching hysteresis is raised by a in the connecting line to the high-level supply terminal Vcc inserted additional resistance R8 in cooperation with the load resistor R3 on the intrinsic hysteresis of the reset controller V3.

Furthermore, there is the possibility of the output voltage of the switching regulator, ie the supply voltage, according to 5 by raising a Z-diode V5 inserted in the connection line to the high-side supply terminal Vcc of the reset controller V3. The supply voltage is increased here by the amount of the Z voltage.

Also, the embodiments of the switching regulator according to the invention 4 and 5 still sufficiently demonstrate the mentioned advantages over the known switching regulator 1 on.

The present invention is not limited to the above-described embodiments. This is how the explanations follow 4 and 5 combine with each other.

Claims (6)

Operating in shunt mode switching regulator, comprising - a storage capacitor (C1) which is charged via a charging diode (V2) by a current transformer and a rectifier arrangement having at least one current source (I) and its charging voltage, the supply voltage for the switching regulator itself and an electrical load (R _L ) forms, - a switching transistor (V1), the current source (I) short-circuits or releases for recharging when an upper switching threshold or when falling below a lower threshold of the charging voltage, and - a controlled by the charging voltage PWM regulator which has a comparator circuit equipped with a switching hysteresis and a reference voltage source and controls the switching transistor (V1) via a resistor divider (R1, R2), characterized in that - the PWM regulator consists of a hysteresis reset controller (V3) whose supply connections (Vcc, GND) at least indirectly with the S and the reset output (Reset) controls the switching transistor (V1). Switching regulator according to the preceding claim, characterized characterized in that between the reset output and the high Supply connection (Vcc) of the reset controller (V3) a working resistor (R3) is arranged. Switching regulator according to the preceding claim, characterized characterized in that between the high-level supply connection (Vcc) and the storage capacitor (C1) an additional resistor (R8) is arranged. Switching regulator according to one of the preceding claims, characterized characterized in that between the high-level supply connection (Vcc) of the reset controller (V3) and the storage capacitor (C1) a Zener diode (V5) is arranged. Switching regulator according to one of Claims 1 to 4, characterized that the non-inverting type reset controller and the switching transistor (V1) is of the type N-channel MOSFET. Switching regulator according to one of Claims 1 to 4, characterized that the inverting type reset controller and the switching transistor (V1) of the type P-channel MOSFET is.